Pairs are, essentially, defined like this:

```
data (,) a b = (,) a b
```

The `Functor`

class looks like this:

```
class Functor f where
fmap :: (a -> b) -> f a -> f b
```

Since the types of function arguments and results must have kind `*`

(i.e. they represent values rather than type functions that can be applied further or more exotic things), we must have `a :: *`

, `b :: *`

, and, most importantly for our purposes, `f :: * -> *`

. Since `(,)`

has kind `* -> * -> *`

, it must be applied to a type of kind `*`

to obtain a type suitable to be a `Functor`

. Thus

```
instance Functor ((,) x) where
-- fmap :: (a -> b) -> (x,a) -> (x,b)
```

So there's actually no way to write a `Functor`

instance doing anything else.

One useful class that offers more ways to work with pairs is `Bifunctor`

, from `Data.Bifunctor`

.

```
class Bifunctor f where
bimap :: (a -> b) -> (c -> d) -> f a c -> f b d
bimap f g = first f . second g
first :: (a -> b) -> f a y -> f b y
first f = bimap f id
second :: (c -> d) -> f x c -> f x d
second g = bimap id g
```

This lets you write things like the following (from `Data.Bifunctor.Join`

):

```
newtype Join p a =
Join { runJoin :: p a a }
instance Bifunctor p => Functor (Join p) where
fmap f = Join . bimap f f . runJoin
```

`Join (,)`

is then essentially the same as `Pair`

, where

```
data Pair a = Pair a a
```

Of course, you can also just use the `Bifunctor`

instance to work with pairs directly.